GUN-MOUNTED SEARCH LIGHT
The improvements include an illuminator for a gun comprising a manually manipulated and storable external IR filter with a plurality of radially directed circumferential tabs integrally extending from the frame to allow a manual torque to be applied to the frame to manually screw it into and out of the bezel in the field, A high g-force diaphragm shock mount for the lamp includes a receptacle which positions the longitudinal axis of the lamp on the optical axis of the reflector. The field serviceable lamp assembly is an integrated or modular and sealed unit. A field serviceable electronics module is accessed by removing the rear bezel. The illuminator handle includes a double locked latch lever. A T-Slot to Picatinny adapter allows a SureFire T-rail fitting of the handle to fit a conventional Picatinny rail.
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The present application is related to U.S. Provisional Patent Application Ser. No. 61/313,627, filed on Mar. 12, 2010, which is incorporated herein by reference and to which priority is claimed pursuant to 35 USC 119.
BACKGROUND OF THE INVENTION1. Field of the Invention
The invention relates to the field of accessories for weapons and in particular to a gun-mounted arc search light.
2. Description of the Prior Art
The HellFighter® target illuminator manufactured by the assignee of the illustrated embodiments of the disclosed invention is designed primarily for use on .50 caliber machine guns. Its shock-isolated 35 W HID lamp has an output of approximately 3,000 lumens and is powered by either two 5590 military batteries or the cigarette lighter adapter. The HellFighter® target illuminator also can be used as a portable, handheld light by detaching it from the T-mount and using the integrated handle.
While the HellFighter® target illuminator is a successfully battle-tested gun-mounted accessory, it is possible to make the HellFighter® target illuminator even more versatile and to improve its performance even more by including the following disclosed improvements in it.
BRIEF SUMMARY OF THE INVENTIONThe illustrated embodiments of the invention include an apparatus or more specifically an illuminator or searchlight used with or mounted on a gun or vehicle. The illuminator includes a reflector having an optical axis and a focus on the optical axis, a lamp, a receptacle for positioning the lamp on the optical axis, and a resilient g-force diaphragm shock mount coupling the receptacle to the reflector which allows bidirectional translation of the receptacle and lamp relative to the reflector. The lamp is bidirectionally translatable on the optical axis to zoom focus a beam produced by light from the lamp as redirected by the reflector while maintaining precise positioning of the lamp to preserve selected stable optical performance of the apparatus despite any application of &force shocks.
The apparatus further includes a thrust assembly coupled to the receptacle for selectively translating the receptacle on the optical axis so that the lamp and reflector are relatively movable with respect to each other to selectively adjust the lamp with respect to the focus.
The apparatus further includes a body. The g-force diaphragm shock mount comprises a bellows diaphragm, the outer circumferential edge of which bellows diaphragm is fixed directly or indirectly to the body of the apparatus, the inner circumferential edge of the bellows diaphragm being fixed directly or indirectly to the receptacle.
A radial portion of the bellows diaphragm is planar, curved, corrugated by a plurality of concentric rings, or shaped into a dimpled diamond pattern, so that the bellows diaphragm acts as a bellows spring to allow the receptacle to move bidirectionally along the longitudinal axis of the lamp or optical axis, while the bellows diaphragm is stiff or rigid in every radial direction relative to the receptacle or the optical axis.
More particularly, the apparatus includes a body and where the g-force diaphragm shock mount comprises a pair of bellows diaphragms, the outer circumferential edges of which bellows diaphragms are fixed directly or indirectly to the body of the apparatus, the inner circumferential edges of the bellows diaphragms being fixed directly or indirectly to the receptacle, the bellows diaphragms being spaced apart by a predetermined distance along the longitudinal axis of the lamp to provide a stable fore and aft support and fixation of the receptacle and hence the lamp.
In this embodiment as well, a radial portion of each of the bellows diaphragms is planar, curved, corrugated by a plurality of concentric rings, or shaped with a diamond pattern, so that the bellows diaphragms act as bellow springs to allow the receptacle to move bidirectionally along the longitudinal axis of the lamp or optical axis, the bellows diaphragms being stiff or rigid in every radial direction relative to the receptacle or the optical axis.
During initial assembly of the apparatus the resilient g-force diaphragm shock mount is preloaded to maintain the thrust assembly under a continuous force. Because of the continuous force, any backlash in the thrust assembly is eliminated in both directions of zoom focus so that the lamp operates in a stable, controlled manner notwithstanding any vibration and g-loads to which the apparatus may be subjected.
The thrust assembly and receptacle are arranged and configured with respect to each other so that during zoom focus there exists a relative “zero” configuration of the thrust assembly and receptacle in which the receptacle is under a nil force allowing disassembly of the apparatus without release of a spring loaded force.
The thrust assembly includes a reversible motor and an indexing assembly for providing a bidirectional limitation of lamp longitudinal displacement, which indexing assembly is screw driven by the reversible motor or manually, the indexing assembly comprising a plurality of index levers, a rotation stop, and an ordered plurality of rotatable index rings, each ring carrying a corresponding index lever to drive the index ring next in the ordered plurality for at least part of a rotation, the last one of the ordered plurality of index rings bearing against the rotation stop after being rotated by a predetermined amount, at least one of the index rings being coupled to the thrust assembly so that lamp longitudinal displacement is effected by rotation of the rings.
In another embodiment the thrust assembly includes a rotating cam assembly for providing a bidirectional limitation of lamp longitudinal displacement by the thrust assembly.
The thrust assembly and receptacle are arranged and configured with respect to each other so that during zoom focus there exists a relative “zero” configuration of the thrust assembly and receptacle in which the receptacle is under a nil force allowing disassembly of the apparatus without release of a spring loaded force, where the thrust assembly further comprises an insertable index pin, where the last one of the ordered plurality of index rings has a plurality of holes defined therein on a predetermined radius for receiving the index pin, where the “zero” configuration is adjusted and defined by selective placement of the index pin into a selected one of the plurality of holes.
The thrust assembly includes a reversible motor and a threaded collar threadably coupled to the receptacle and rotated by the reversible motor, the collar having a stop defined therein and a predetermined length of a collar being threaded with a pitch to allow only a predetermined number of revolutions before the stop on the collar is reached, thereby providing a bidirectional limitation of lamp longitudinal displacement.
The illustrated embodiments of the invention also include an external filter for an illuminator with an aperture defined in a bezel having a threaded inner edge. The filter includes a circular frame with an outer circumferential thread which threads into the inner edge of the bezel of the illuminator, the frame having a plurality of inwardly radially directed circumferential tabs integrally extending from the frame and coplanar therewith to allow a directly applied manual torque to screw the frame into and out of the bezel, and an IR, amber or other optical filter extending across and covering the aperture of the frame.
The illuminator includes a rear threaded cavity into which the IR optical filter is adapted to be threadably engaged and stored in a protected configuration.
The filter further includes an elastic opaque dust cap resiliently disposed over the bezel to provide mechanical protection for the bezel and filter when not in use in those cases where the filter is left in the operative configuration over the aperture.
The dust cap is arranged and configured to be resiliently disposed over the rear cavity to provide sealed closure thereof.
The filter further includes a detent mechanism incorporated into the frame of the filter and bezel to retain the frame of the filter within the bezel.
The illustrated embodiments of the invention also include an internal IR filter assembly for an illuminator having a lamp disposed within a reflector with a face plate. The internal IR filter assembly includes an IR filter shaped as a hollow sleeve telescopically disposable over the lamp, a fixed cylindrical pedestal having one end coupled to the face plate, a sliding cylindrical mount coupled on one end to the IR filter and telescopically disposed over the fixed pedestal, and a thrust assembly coupled to the cylindrical mount for selectively bidirectionally translating the cylindrical mount over the pedestal and bidirectionally translating the IR filter over the lamp.
The thrust assembly includes a thrust lever coupled to the sliding cylindrical mount for telescopically bidirectionally translating the cylindrical mount over the pedestal and bidirectionally translating the IR filter over the lamp, a drive pin rotatably coupled to the thrust lever, and a reversibly rotating cam operatively engaging the drive pin to selectively bidirectionally translate the drive pin.
The reflector has an optical axis, and the pedestal is aligned with the optical axis of the reflector and is hollow to permit the disposition of a lamp lead therethrough.
The internal IR filter assembly further includes a spring. The sliding cylindrical mount is biased by the spring which is coaxially disposed about pedestal and compressed between the pedestal and the sliding cylindrical mount.
The illustrated embodiments of the invention also include a field serviceable illuminator which includes a housing, a lamp, a reflector with an optical axis, a lamp receptacle for holding and positioning the lamp and at least one bellows diaphragm for holding and positioning the lamp receptacle relative to the optical axis of the reflector. The lamp, reflector, lamp receptacle and bellows diaphragm or any subgroup thereof are disposed in the housing, and are arranged and configured as an integrated, modular and sealed unit disposable in the housing replaceable in the field without specialized tools.
The field serviceable illuminator further includes a plug-in field serviceable electronics module disposed in the housing, the housing comprising a removable rear bezel, which is accessed by removing the rear bezel from the housing, all of the electronics needed to operate the illuminator being included in the plug-in, field serviceable electronics module, so that if there is any electronic malfunction of the illuminator in the field, all of the electronics needed for operation is readily removed in the field by removal of the rear bezel, dropping out the defective electronics module, inserting a replacement plug-in electronics module, and reattaching the rear bezel without any further attention or consideration of the details of electronic functions or mountings.
The field serviceable illuminator is used in combination with a lamp control cable coupled to the illuminator which cable is arranged and configured to lead forward or aft of the illuminator. The illuminator further includes an angled cable connector connected to the outside of the housing of the illuminator which connector includes an angled mounting face, where the face is angled relative to the longitudinal axis of the housing in the direction of the lead of the cable to allow for a reduced bend of the cable.
The illustrated embodiments of the invention also include a fast start, infrared enhanced HID lamp which is characterized by the addition within the lamp of finely granulated metal halide salts into the lamp envelope.
The illustrated embodiments of the invention also include an illuminator handle adapted for coupling to an illuminator and for coupling the illuminator to a T-bar rail. The handle includes a handle body, a T-bar engaging channel defined in the handle body having a T-rail slot defined in the channel and an open end of the channel, a stop block disposed at an end of the channel opposing the open end, a double-locked latch lever assembly disposed in the handle body and positioned near or at the open end of the channel, the latch lever assembly including a latch lever, where the latch lever is arranged and configured to be manipulated with one hand to lock the handle onto the T-bar rail with the same hand used to mount the handle and illuminator onto the T-bar rail, a spring biased latch block assembly including a latch block coupled to the latch lever and disposable into the T-rail slot and adapted to capture any T-rail segment disposed between the latch block and the stop block, the latch block being movable between an up- and down-position by means of engagement with the latch lever, when in the down-position the latch block is inserted into the T-slot in the channel, and a spring biased rocker latch disposed at least in part in the handle body and engagable with the latch block to lock the latch block in the down-position, the rocker latch being biased into the locked position, when in the up-position the latch block is withdrawn from the T-slot in the channel and locked in the up-position.
The latch block assembly includes a latch block pin to which the latch block is rotatably coupled, the latch block pin being slidingly captured within a fork on an end of the latch lever, the latch lever being rotatably coupled to the handle body, so that the latch block is upwardly and downwardly movable by movement of the latch lever. The latch block is biased into the down-position by at least one spring and inserted into the T-slot in the channel. The rocker latch has a lower flange rotatable into a position above the latch block to lock the latch block in the down-position. The rocker latch is biased into the locking configuration by at least one spring, when in the up-position in which the latch block is withdrawn from the T-slot in the channel. The lower flange of the rocker latch is rotatable outward against spring bias to allow the latch lever to raise the latch block past the lower flange of the rocker latch and is rotatable inward into a position extending the lower flange of the rocker latch below the latch block to lock the latch block in the up-position.
The illuminator handle further includes a T Slot-to-Picatinny adapter whereby the handle is coupled to a conventional Picatinny rail. The adapter includes a T-rail slot, which is defined on one surface of the adapter for coupling into the channel of the handle, and a Picatinny rail coupling provided on the opposing surface of the adapter. The Picatinny rail coupling includes a plurality of bolts, a body of the adapter, a fixed rail extending from the body, a separable movable or cammed rail which is coupled to the fixed rail by means of the plurality of bolts which are threaded into the fixed rail and which extend across the Picatinny rail coupling.
The illustrated embodiments of the invention also include a remote controller handle for a controllable illuminator. The remote controller handle includes a body including an ergonomic hand grip, a main off/on switch, a handgrip assembly pushbutton, and a side cavity in which a plurality of sealed pushbutton switches for additional light functions are mounted which allow one-hand, finger activation of selected ones of the plurality of momentary and/or click pushbutton switches to control zoom out, zoom in, electronic IR filter control and other light and filter control commands.
The illustrated embodiments include a method of providing or operating any one of the above embodiments.
While the apparatus and method has or will be described for the sake of grammatical fluidity with functional explanations, it is to be expressly understood that the claims, unless expressly formulated under 35 USC 112, are not to be construed as necessarily limited in any way by the construction of “means” or “steps” limitations, but are to be accorded the full scope of the meaning and equivalents of the definition provided by the claims under the judicial doctrine of equivalents, and in the case where the claims are expressly formulated under 35 USC 112 are to be accorded full statutory equivalents under 35 USC 112. The invention can be better visualized by turning now to the following drawings wherein like elements are referenced by like numerals.
The invention and its various embodiments can now be better understood by turning to the following detailed description of the preferred embodiments which are presented as illustrated examples of the invention defined in the claims. It is expressly understood that the invention as defined by the claims may be broader than the illustrated embodiments described below.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTSThe improvements included in the illustrated embodiments of the invention include the following.
Manually Manipulated and Storable External IR Filter
An elastic or rubberized opaque dust cap 30, shown in a rear storage position in
When filter 12 is not to be used and is manually removed, it can readily be stored in a storage space 38 defined in the rear end of illuminator 10 in a threaded rear bezel 32, shown in the configuration of
Level Driven and Storable Internal IR Filter
Mount 13 is telescopically disposed over a fixed cylindrical pedestal 15, which has its forward or distal end 17 fixed to the center of faceplate 19 of reflector 50. Cylindrical pedestal 15 is aligned with the optical axis 52 of reflector 50 as shown in
Cam 39 is in the form of a cylinder disposed and journaled outside the radius of the mechanism including thrust collar 90 and threaded bushing 92 described above in connection with
A similar cylindrical cam (not shown), reversibly driven by an electric motor, can be substituted for the ring indexing assembly in
Gear Driven and Storable Internal IR Filter
Detent Retention of IR Filter
An enlarged side cross-sectional partial view of a lower edge of front bezel 28 is depicted in
It must be understood that other configurations are possible for plunger 186 and the same function can be realized. For example, if desired, plunger 186 can be radially disposed into tabs 22 in the forward edge of frame 20 and the grooves or socket holes 196 defined in the forward edge of bezel 28 or the reverse, namely the plunger 186 disposed in the forward edge of bezel 28 and the grooves or socket holes 196 disposed in the forward edge of frame 20, and aligned with tabs 22 or not.
High G-Force Diaphragm Shock Mount for the Lamp
The lamp mounting assembly shown in
In order to maintain the rigidity of the lamp mounting assembly in this environment while still allowing lamp 42 to be precisely translated along the optical axis 52, receptacle 44 is held in position by a pair of bellows diaphragms 58a and 58b. The outer circumferential edges of bellows diaphragms 58a and 58b are fixed directly or indirectly to body 60 of illuminator 10. The inner circumferential edges of bellows diaphragms 58a and 58b are fixed directly or indirectly to receptacle 44. Bellows diaphragms 58a and 58b are spaced apart by a predetermined distance along the longitudinal axis of lamp 42 to provide a stable fore and aft support and fixation of receptacle 44 and, hence, lamp 42. A radial portion of each of bellows diaphragms 58a and 58b is corrugated by a plurality of concentric rings so that bellows diaphragms 58a and 58b act as bellows springs to allow thrust assembly 46 to move receptacle 44 bidirectionally along the longitudinal axis of lamp 42. However, bellows diaphragms 58a and 58b are extremely stiff or rigid in every radial direction relative to receptacle 44 and the optical axis 52. This feature is particularly useful when it is understood that as the gun elevation is raised relative to the search light beam for distant targets, much of the shock force on illuminator 10 will have a large radial component.
It is also within the scope of the invention that bellows diaphragms 58a and 58b could be replaced by dual springs contained within a longitudinally fixed telescopic or sliding mechanism to provide radial rigidity without interference with longitudinal elasticity.
Movement in the longitudinal direction along optical axis 52 is controlled and limited by virtue of the coupling of receptacle 44 to thrust assembly 46, which itself is rigidly fixed relative to body 60. High-G gun vibrations or shocks, which are transmitted to receptacle 44 and lamp 42, therefore cannot produce any relative movement of receptacle 44 or lamp 42 with respect to reflector 50, which in turn is also directly or indirectly rigidly coupled to body 60, and hence cannot produce any relative movement of receptacle 44 or lamp 42 with respect to optical axis 52. The optical performance of illuminator 10 is unaffected by high-G shocks without any limitation in the ability to move lamp 42 along the optical axis 52 for zoom operation.
During initial assembly bellows diaphragms 58a and 58b are preloaded or biased to maintain the threading within thrust assembly 46 under a continuous force or bias. Because of the continuous bias, the backlash normally experienced in all threaded mechanisms is eliminated in both directions of zoom adjustment. Because of the relatively high longitudinal bias provided by bellows diaphragms 58a and 58b as compared to thread biasing arrangement in other zoom mechanisms known in the art which use the compression of elastic O-rings, the zoom focus of lamp 42 operates in a steady and controlled manner notwithstanding high vibration and g-loads to which illuminator 10 is subjected when rigidly coupled to a firing gun.
Rotational Limitation of Lamp Longitudinal Displacement
Rotation of driven gear 88 is limited to three turns by two corresponding rotatable index rings 94 and 96, which are free to rotate around threaded bushing 92. An index post 98 extends from rear surface of driven gear 88. Post 98 begins from an initial position as shown in
It is to be expressly understood that the number of index rings and arms can be easily added or deleted from thrust assembly 46 without requiring redesign or remanufacture of illuminator 10 so that the number of turns which can be provided can be varied. Further, it is also possible to eliminate the index rings and arms and instead change the length of collar 90 which is threaded and change the pitch of threading to allow only a predetermined number of revolutions before a stop on collar 90 is reached. In such a case the threading would be finished at each end of collar 90 so that a threading jam or lock would not be realized.
However, utilizing a measured threaded drive section on collar 90 as suggested above requires demanding manufacturing and assembly tolerances, since thrust assembly 46 is positioned relative to receptacle 44 so that there is a zero position in which a small gap is provided between thrust assembly 96 and receptacle 44 having tolerances on the order of 0.0010's of an inch at the zero position of bellows diaphragms 58a and 58b. This zero position is required to provide a configuration where the lamp assembly and related elements can be accessed in a nonbiased configuration to avoid damaging those elements. However, the tolerance must be held to a predetermined minimum to avoid backlash and to insure responsive and precise zoom operation. The index ring and arm embodiment provides the solution to these design constraints by providing a plurality of holes 198 in gear 88 as shown in the plan view of
Field Serviceable Lamp Assembly
In contrast in the illustrated embodiment a user in the field using the illuminator 10 is able to unscrew retainer ring 64 shown in
Fast Start, Infrared Enhanced HID Lamp
In one of the illustrated embodiments, lamp 42 is modified as compared to conventional HID lamps by the addition of finely granulated metal halide salts into the lamp envelope. Conventional HID lamps are designed to minimize the generation of IR light. However, the illustrated embodiment includes the addition of metal halide salts which enhance selected IR lines or IR spectral segments. The presence of such metal halide salts allows their incorporation into the plasma ball, which in turn results in a substantially higher production of infrared light as compared to conventional HID lamps not having such metal halide salts added.
The electronic ballast in illuminator 10 is designed to provide rapid starting of lamp 42, namely more than 80% of the final lumen output within one second or less, and provides arc stability. The fast start performance of illuminator 10 is graphically depicted in
Field Serviceable Electronics Module
Angled Cable Connector
Illuminator Handle
Illuminator 10 was provided with a handle 78 as shown in the prior art view of
Handle 178 is better understood by viewing the exploded perspective view of
The locking mechanism of handle 178 is best understood by starting with the longitudinally cutaway perspective view of
Pin 124 is slidingly captured within a fork 126 on the end of latch lever 108 as best seen in
Similarly, when in the up-position in which latch block 118 is fully withdrawn from the T-slot in channel 106, lower flange 132 is first rotated outward to allow latch lever 108 to raise latch block 118 and then latch lever 130 is allowed to rotate back into the position shown in
T-Slot to Picatinny Adapter
Remote Controller Handle
Another improvement of the illustrated embodiments of the invention is shown in perspective view in
Body 172 of the remote controller handle in
Body 172 of the remote controller handle in
Many alterations and modifications may be made by those having ordinary skill in the art without departing from the spirit and scope of the invention. Therefore, it must be understood that the illustrated embodiment has been set forth only for the purposes of example and that it should not be taken as limiting the invention as defined by the following invention and its various embodiments.
For example,
Therefore, it must be understood that the illustrated embodiment has been set forth only for the purposes of example and that it should not be taken as limiting the invention as defined by the following claims. For example, notwithstanding the fact that the elements of a claim are set forth below in a certain combination, it must be expressly understood that the invention includes other combinations of fewer, more or different elements, which are disclosed above even when not initially claimed in such combinations. A teaching that two elements are combined in a claimed combination is further to be understood as also allowing for a claimed combination in which the two elements are not combined with each other but may be used alone or combined in other combinations. The excision of any disclosed element of the invention is explicitly contemplated as within the scope of the invention.
The words used in this specification to describe the invention and its various embodiments are to be understood not only in the sense of their commonly defined meanings, but to include by special definition in this specification structure, material or acts beyond the scope of the commonly defined meanings. Thus if an element can be understood in the context of this specification as including more than one meaning, then its use in a claim must be understood as being generic to all possible meanings supported by the specification and by the word itself.
The definitions of the words or elements of the following claims are, therefore, defined in this specification to include not only the combination of elements which are literally set forth, but all equivalent structure, material or acts for performing substantially the same function in substantially the same way to obtain substantially the same result. In this sense it is therefore contemplated that an equivalent substitution of two or more elements may be made for any one of the elements in the claims below or that a single element may be substituted for two or more elements in a claim. Although elements may be described above as acting in certain combinations and even initially claimed as such, it is to be expressly understood that one or more elements from a claimed combination can in some cases be excised from the combination and that the claimed combination may be directed to a subcombination or variation of a subcombination.
Insubstantial changes from the claimed subject matter as viewed by a person with ordinary skill in the art, now known or later devised, are expressly contemplated as being equivalently within the scope of the claims. Therefore, obvious substitutions now or later known to one with ordinary skill in the art are defined to be within the scope of the defined elements.
The claims are thus to be understood to include what is specifically illustrated and described above, what is conceptionally equivalent, what can be obviously substituted and also what incorporates the essential idea of the invention.
Claims
1. An apparatus comprising:
- a reflector having an optical axis and a focus on the optical axis;
- a lamp;
- a receptacle for positioning the lamp on the optical axis; and
- a resilient g-force diaphragm shock mount coupling the receptacle to the reflector which allows bidirectional translation of the receptacle and lamp relative to the reflector,
- where the lamp is bidirectionally translatable on the optical axis to zoom focus a beam produced by light from the lamp as redirected by the reflector while maintaining precise positioning of the lamp to preserve selected stable optical performance of the apparatus despite any application of G-force shocks.
2. The apparatus of claim 1 further comprising a thrust assembly coupled to the receptacle for selectively translating the receptacle on the optical axis so that the lamp and reflector are relatively movable with respect to each other to selectively adjust the lamp with respect to the focus.
3. The apparatus of claim 1 further comprising a body and where the g-force diaphragm shock mount comprises a bellows diaphragm, the outer circumferential edge of which bellows diaphragm is fixed directly or indirectly to the body of the apparatus, the inner circumferential edge of the bellows diaphragm being fixed directly or indirectly to the receptacle.
4. The apparatus of claim 3 where a radial portion of the bellows diaphragm is planar, curved, corrugated by a plurality of concentric rings, or shaped into a dimpled diamond pattern, so that the bellows diaphragm acts as a bellows spring to allow the receptacle to move bidirectionally along the longitudinal axis of the lamp or optical axis, while the bellows diaphragm is stiff or rigid in every radial direction relative to the receptacle or the optical axis.
5. The apparatus of claim 1 further comprising a body and where the g-force diaphragm shock mount comprises a pair of bellows diaphragms, the outer circumferential edges of which bellows diaphragms are fixed directly or indirectly to the body of the apparatus, the inner circumferential edges of the bellows diaphragms being fixed directly or indirectly to the receptacle, the bellows diaphragms being spaced apart by a predetermined distance along the longitudinal axis of the lamp to provide a stable fore and aft support and fixation of the receptacle and hence the lamp.
6. The apparatus of claim 5 where a radial portion of each of the bellows diaphragms is planar, curved, corrugated by a plurality of concentric rings, or shaped with a diamond pattern, so that the bellows diaphragms act as bellow springs to allow the receptacle to move bidirectionally along the longitudinal axis of the lamp or optical axis, the bellows diaphragms being stiff or rigid in every radial direction relative to the receptacle or the optical axis.
7. The apparatus of claim 2 where during initial assembly of the apparatus the resilient g-force diaphragm shock mount is preloaded to maintain the thrust assembly under a continuous force, where because of the continuous force, any backlash in the thrust assembly is eliminated in both directions of zoom focus so that the lamp operates in a stable, controlled manner notwithstanding any vibration and g-loads to which the apparatus may be subjected.
8. The apparatus of claim 7 where the thrust assembly and receptacle are arranged and configured with respect to each other so that during zoom focus there exists a relative “zero” configuration of the thrust assembly and receptacle in which the receptacle is under a nil force allowing disassembly of the apparatus without release of a spring loaded force.
9. The apparatus of claim 2 where the thrust assembly comprises a reversible motor and an indexing assembly for providing a bidirectional limitation of lamp longitudinal displacement, which indexing assembly is screw driven by the reversible motor or manually, the indexing assembly comprising a plurality of index levers, a rotation stop, and an ordered plurality of rotatable index rings, each ring carrying a corresponding index lever to drive the index ring next in the ordered plurality for at least part of a rotation, the last one of the ordered plurality of index rings bearing against the rotation stop after being rotated by a predetermined amount, at least one of the index rings being coupled to the thrust assembly so that lamp longitudinal displacement is effected by rotation of the rings.
10. The apparatus of claim 2 where the thrust assembly comprises a rotating cam assembly for providing a bidirectional limitation of lamp longitudinal displacement by the thrust assembly.
11. The apparatus of claim 9 where the thrust assembly and receptacle are arranged and configured with respect to each other so that during zoom focus there exists a relative “zero” configuration of the thrust assembly and receptacle in which the receptacle is under a nil force allowing disassembly of the apparatus without release of a spring loaded force, where the thrust assembly further comprises an insertable index pin, where the last one of the ordered plurality of index rings has a plurality of holes defined therein an a predetermined radius for receiving the index pin, where the “zero” configuration is adjusted and defined by selective placement of the index pin into a selected one of the plurality of holes.
12. The apparatus of claim 2 where the thrust assembly comprises a reversible motor and a threaded collar threadably coupled to the receptacle and rotated by the reversible motor, the collar have a stop defined therein and a predetermined length of a collar being threaded with a pitch to allow only a predetermined number of revolutions before the stop on the collar is reached thereby providing a bidirectional limitation of lamp longitudinal displacement.
13. An external filter for an illuminator with an aperture defined in a bezel having a threaded inner edge comprising:
- a circular frame with a outer circumferential thread which threads into the inner edge of the bezel of the illuminator, the frame having a plurality of inwardly radially directed circumferential tabs integrally extending from the frame and coplanar therewith to allow a directly applied manual torque to screw the frame into and out of the bezel; and
- an IR optical filter extending across and covering the aperture of the frame.
14. The filter of claim 13 where the illuminator includes a rear threaded cavity into which the IR optical filter is adapted to be threadably engaged and stored in a protected configuration.
15. The filter of claim 13 further comprising an elastic opaque dust cap resiliently disposed over the bezel to provide mechanical protection for the bezel and filter when not in use in those cases where filter is left in the operative configuration over the aperture.
16. The filter of claim 14 where the dust cap is arranged and configured to be resiliently disposed over the rear cavity to provide sealed closure thereof.
17. The filter of claim 13 further comprising a detent mechanism incorporated into the frame of the filter and bezel to retain the frame of the filter within the bezel.
18. A field serviceable illuminator comprising:
- a housing;
- a lamp;
- a reflector with an optical axis;
- a lamp receptacle for holding and positioning the lamp; and
- at least one bellows diaphragm for holding and positioning the lamp receptacle relative to the optical axis of the reflector,
- where the lamp, reflector, lamp receptacle and bellows diaphragm or any subgroup thereof are disposed in the housing, and are arranged and configured as an integrated, modular and sealed unit disposable in the housing replaceable in the field without specialized tools.
19. The field serviceable illuminator of claim 18 further comprising a plug-in field serviceable electronics module disposed in the housing, the housing comprising a removable rear bezel, which is accessed by removing the rear bezel from the housing, all of the electronics needed to operate the illuminator being included in the plug-in, field serviceable electronics module, so that if there is any electronic malfunction of the illuminator in the field, all of the electronics needed for operation is readily removed in the field by removal of the rear bezel, dropping out the defective electronics module, inserting a replacement plug-in electronics module, and reattaching the rear bezel without any further attention or consideration of the details of electronic functions or mountings.
20. The field serviceable illuminator of claim 18 in combination with a lamp control cable coupled to the illuminator arranged and configured to lead forward or aft of the illuminator and further comprising an angled cable connector connected to the outside of the housing of the illuminator which connector includes an angled mounting face, where the face is angled relative to the longitudinal axis of the housing in the direction of the lead of the cable to allow for a reduced bend of the cable.
21. An apparatus comprising a fast start, infrared enhanced HID lamp which is characterized by the addition within the lamp of finely granulated metal halide salts into the lamp envelope.
22. An illuminator handle adapted for coupling to an illuminator and for coupling the illuminator to a T-bar rail comprising:
- a handle body;
- a T-bar engaging channel defined in the handle body having a T-rail slot defined in the channel and an open end of the channel;
- a stop block disposed at an end of the channel opposing the open end;
- a double-locked latch lever assembly disposed in the handle body and positioned near or at the open end of the channel, the latch lever assembly including a latch lever, where the latch lever is arranged and configured to be manipulated with one hand to lock the handle onto the T-bar rail with the same hand used to mount the handle and illuminator onto the T-bar rail;
- a spring biased latch block assembly including a latch block coupled to the latch lever and disposable into the T-rail slot and adapted to capture any T-rail segment disposed between the latch block and the top block, the latch block being movable between an up- and down-position by means of engagement with the latch lever, when in the down-position the latch block is inserted into the T-slot in the channel; and
- a spring biased rocker latch disposed at least in part in the handle body and engagable with the latch block to lock the latch block in the down-position, the rocker latch being biased into the locked position, when in the up-position the latch block is withdrawn from the T-slot in the channel and locked in the up-position.
23. The illuminator handle of claim 22 where the latch block assembly comprises a latch block pin to which the latch block is rotatably coupled, the latch block pin being slidingly captured within a fork on an end of latch lever, the latch lever being rotatably coupled to the handle body, so that the latch block is upwardly and downwardly movable by movement of the latch lever, the latch block being biased into the down-position by at least one spring and inserted into the T-slot in the channel, the rocker latch having a lower flange rotatable into a position above the latch block to lock the latch block in the down-position, the rocker latch being biased into the locking configuration by at least one spring, when in the up-position in which the latch block is withdrawn from the T-slot in the channel, the lower flange of the rocker latch being rotatable outward against spring bias to allow the latch lever to raise the latch block past the lower flange of the rocker latch and being rotatable inward in to a position extending the lower flange of the rocker latch below the latch block to lock latch block in the up-position.
24. The illuminator handle of claim 22 further comprising a T Slot-to-Picatinny adapter whereby the handle is coupled to a conventional Picatinny rail, the adapter comprising;
- a T-rail slot is defined on one surface of the adapter for coupling into the channel of the handle; and
- a Picatinny rail coupling provided on the opposing surface of the adapter;
- where the Picatinny rail coupling comprises a plurality of bolts, a body of the adapter, a fixed rail extending from the body, a separable movable or cammed rail which is coupled to the fixed rail by means of the plurality of bolts which are threaded into the fixed rail and which extend across the Picatinny rail coupling.
25. A remote controller handle for a controllable illuminator comprising:
- a body including an ergonomic hand grip;
- a main off/on switch,
- a handgrip assembly pushbutton; and
- a side cavity in which a plurality of sealed pushbutton switches for additional light functions are mounted which allow one-hand, finger activation of selected ones of the plurality of momentary and/or click pushbutton switches to control zoom out, zoom in, electronic IR filter control and other light and filter control commands.
26. An internal IR filter assembly for an illuminator having a lamp disposed within a reflector with a face plate comprising:
- an IR filter shaped as a hollow sleeve telescopically disposable over the lamp;
- a fixed cylindrical pedestal having one end coupled to the face plate;
- a sliding cylindrical mount coupled on one end to the IR filter and telescopically disposed over the fixed pedestal; and
- a thrust assembly coupled to the cylindrical mount for selectively bidirectionally translating the cylindrical mount over the pedestal and bidirectionally translating the IR filter over the lamp.
27. The internal IR filter assembly of claim 26 where the thrust assembly comprises a thrust lever coupled to the sliding cylindrical mount for telescopically bidirectionally translating the cylindrical mount over the pedestal and bidirectionally translating the IR filter over the lamp, a drive pin rotatably coupled to the thrust lever, and a reversibly rotating cam operatively engaging the drive pin to selectively bidirectionally translate the drive pin.
28. The internal IR filter assembly of claim 26 where the reflector has an optical axis, where the pedestal is aligned with the optical axis of the reflector and is hollow to permit the disposition of a lamp lead there through.
29. The internal IR filter assembly of claim 26 further comprising a spring and where the sliding cylindrical mount is biased by the spring which is coaxially disposed about pedestal and compressed between the pedestal and the sliding cylindrical mount.
30. The internal IR filter assembly of claim 26 wherein the thrust assembly comprises a gear drive mechanism and a motor coupled to the gear drive mechanism to selectively and reversibly rotate the gear drive mechanism, the gear drive mechanism being coupled to the sliding cylindrical mount of the IR filter to selectively and reversibly translate the IR filter with respect to the lamp.
31. The internal IR filter assembly of claim 30 wherein the gear drive mechanism comprises a rotatable driving gear coupled to and driven by the motor and a driven gear threadably engaged with the driving gear and selectively and reversibly translated by selective and reversible rotation of the driving gear, the driven gear being coupled to the sliding cylindrical mount of the IR filter to selectively and reversibly translate the IR filter with respect to the lamp.
Type: Application
Filed: Mar 11, 2011
Publication Date: Jan 19, 2012
Patent Grant number: 8613534
Applicant: SureFire LLC (Fountain Valley, CA)
Inventors: Gregory Z. Jigamian (Temecula, CA), Michael D. Picciotta (Yorba Linda, CA), Ronald S. Gibson (Valencia, CA)
Application Number: 13/046,665
International Classification: F21V 7/00 (20060101); F21V 99/00 (20060101); H05B 37/02 (20060101); F21V 9/04 (20060101); F21V 15/04 (20060101);